Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis

Alvaro Seijas-Da Silva; Adrian Hartert; Víctor Oestreicher; Jorge Romero; Camilo Jaramillo-Hernández; Luuk J.J. Muris; Grégoire Thorez; Bruno J.C. Vieira; Guillaume Ducourthial; Alice Fiocco; Sébastien Legendre; Cristián Huck-Iriart; Martín Mizrahi; Diego López-Alcalá; Anna T.S. Freiberg; Karl J.J. Mayrhofer; João C. Waerenborgh; José J. Baldoví; Serhiy Cherevko; Maria Varela; Simon Thiele; Vicent Lloret; Gonzalo Abellán

doi:10.1038/s41467-025-61356-2

Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis

Alvaro Seijas-Da Silva
, Adrian Hartert
, Víctor Oestreicher
, Jorge Romero
, Camilo Jaramillo-Hernández
, Luuk J.J. Muris
, Grégoire Thorez
, Bruno J.C. Vieira
, Guillaume Ducourthial
, Alice Fiocco
, Sébastien Legendre
, Cristián Huck-Iriart
, Martín Mizrahi
, Diego López-Alcalá
, Anna T.S. Freiberg
, Karl J.J. Mayrhofer
, João C. Waerenborgh
, José J. Baldoví
, Serhiy Cherevko
, Maria Varela

Simon Thiele, Vicent Lloret, Gonzalo Abellán^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

25 Citations (Scopus)

Abstract

The alkaline oxygen evolution reaction is a key step in producing green hydrogen through water electrolysis, but its large-scale industrial application remains limited due to challenges with current electrocatalysts—particularly in terms of scalability, efficiency, and long-term stability. Here we show an industrially scalable synthesis of an active NiFe layered double hydroxide (NiFe-LDH) catalyst using a room-temperature, atmospheric-pressure route. The process involves homogeneous alkalinization, where chloride ions nucleophilically attack an epoxide ring, producing a low-dimensional, defect-rich NiFe-LDH with pronounced iron clustering. In-situ spectroscopy and ab-initio calculations reveal that these structural features maximize the conversion of the NiFe-LDH to the catalytic active phase and minimize the energy barrier, improving catalytic efficiency. When used as the anode in an anion exchange membrane water electrolyzer operating at 70 °C, our material delivers 1 A cm⁻² at 1.69 V in a 5 cm² full-cell setup, with notable durability compared to conventional NiFe-LDHs. This scalable approach could considerably lower the cost of green hydrogen production by enabling more efficient alkaline electrolyzers.

Original language	English
Article number	6138
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-61356-2
Publication status	Published - Dec 2025
Externally published	Yes

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Seijas-Da Silva, A., Hartert, A., Oestreicher, V., Romero, J., Jaramillo-Hernández, C., Muris, L. J. J., Thorez, G., Vieira, B. J. C., Ducourthial, G., Fiocco, A., Legendre, S., Huck-Iriart, C., Mizrahi, M., López-Alcalá, D., Freiberg, A. T. S., Mayrhofer, K. J. J., Waerenborgh, J. C., Baldoví, J. J., Cherevko, S., ... Abellán, G. (2025). Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis. Nature Communications, 16(1), Article 6138. https://doi.org/10.1038/s41467-025-61356-2

@article{6fe4392875794e40a231d1b4951fe764,

title = "Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis",

abstract = "The alkaline oxygen evolution reaction is a key step in producing green hydrogen through water electrolysis, but its large-scale industrial application remains limited due to challenges with current electrocatalysts—particularly in terms of scalability, efficiency, and long-term stability. Here we show an industrially scalable synthesis of an active NiFe layered double hydroxide (NiFe-LDH) catalyst using a room-temperature, atmospheric-pressure route. The process involves homogeneous alkalinization, where chloride ions nucleophilically attack an epoxide ring, producing a low-dimensional, defect-rich NiFe-LDH with pronounced iron clustering. In-situ spectroscopy and ab-initio calculations reveal that these structural features maximize the conversion of the NiFe-LDH to the catalytic active phase and minimize the energy barrier, improving catalytic efficiency. When used as the anode in an anion exchange membrane water electrolyzer operating at 70 °C, our material delivers 1 A cm⁻² at 1.69 V in a 5 cm2 full-cell setup, with notable durability compared to conventional NiFe-LDHs. This scalable approach could considerably lower the cost of green hydrogen production by enabling more efficient alkaline electrolyzers.",

author = "\{Seijas-Da Silva\}, Alvaro and Adrian Hartert and V{\'i}ctor Oestreicher and Jorge Romero and Camilo Jaramillo-Hern{\'a}ndez and Muris, \{Luuk J.J.\} and Gr{\'e}goire Thorez and Vieira, \{Bruno J.C.\} and Guillaume Ducourthial and Alice Fiocco and S{\'e}bastien Legendre and Cristi{\'a}n Huck-Iriart and Mart{\'i}n Mizrahi and Diego L{\'o}pez-Alcal{\'a} and Freiberg, \{Anna T.S.\} and Mayrhofer, \{Karl J.J.\} and Waerenborgh, \{Jo{\~a}o C.\} and Baldov{\'i}, \{Jos{\'e} J.\} and Serhiy Cherevko and Maria Varela and Simon Thiele and Vicent Lloret and Gonzalo Abell{\'a}n",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-61356-2",

language = "English",

volume = "16",

journal = "Nature Communications",

issn = "2041-1723",

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number = "1",

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Seijas-Da Silva, A, Hartert, A, Oestreicher, V, Romero, J, Jaramillo-Hernández, C, Muris, LJJ, Thorez, G, Vieira, BJC, Ducourthial, G, Fiocco, A, Legendre, S, Huck-Iriart, C, Mizrahi, M, López-Alcalá, D, Freiberg, ATS, Mayrhofer, KJJ, Waerenborgh, JC, Baldoví, JJ, Cherevko, S, Varela, M, Thiele, S, Lloret, V & Abellán, G 2025, 'Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis', Nature Communications, vol. 16, no. 1, 6138. https://doi.org/10.1038/s41467-025-61356-2

TY - JOUR

T1 - Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis

AU - Seijas-Da Silva, Alvaro

AU - Hartert, Adrian

AU - Oestreicher, Víctor

AU - Romero, Jorge

AU - Jaramillo-Hernández, Camilo

AU - Muris, Luuk J.J.

AU - Thorez, Grégoire

AU - Vieira, Bruno J.C.

AU - Ducourthial, Guillaume

AU - Fiocco, Alice

AU - Legendre, Sébastien

AU - Huck-Iriart, Cristián

AU - Mizrahi, Martín

AU - López-Alcalá, Diego

AU - Freiberg, Anna T.S.

AU - Mayrhofer, Karl J.J.

AU - Waerenborgh, João C.

AU - Baldoví, José J.

AU - Cherevko, Serhiy

AU - Varela, Maria

AU - Thiele, Simon

AU - Lloret, Vicent

AU - Abellán, Gonzalo

PY - 2025/12

Y1 - 2025/12

N2 - The alkaline oxygen evolution reaction is a key step in producing green hydrogen through water electrolysis, but its large-scale industrial application remains limited due to challenges with current electrocatalysts—particularly in terms of scalability, efficiency, and long-term stability. Here we show an industrially scalable synthesis of an active NiFe layered double hydroxide (NiFe-LDH) catalyst using a room-temperature, atmospheric-pressure route. The process involves homogeneous alkalinization, where chloride ions nucleophilically attack an epoxide ring, producing a low-dimensional, defect-rich NiFe-LDH with pronounced iron clustering. In-situ spectroscopy and ab-initio calculations reveal that these structural features maximize the conversion of the NiFe-LDH to the catalytic active phase and minimize the energy barrier, improving catalytic efficiency. When used as the anode in an anion exchange membrane water electrolyzer operating at 70 °C, our material delivers 1 A cm⁻² at 1.69 V in a 5 cm2 full-cell setup, with notable durability compared to conventional NiFe-LDHs. This scalable approach could considerably lower the cost of green hydrogen production by enabling more efficient alkaline electrolyzers.

AB - The alkaline oxygen evolution reaction is a key step in producing green hydrogen through water electrolysis, but its large-scale industrial application remains limited due to challenges with current electrocatalysts—particularly in terms of scalability, efficiency, and long-term stability. Here we show an industrially scalable synthesis of an active NiFe layered double hydroxide (NiFe-LDH) catalyst using a room-temperature, atmospheric-pressure route. The process involves homogeneous alkalinization, where chloride ions nucleophilically attack an epoxide ring, producing a low-dimensional, defect-rich NiFe-LDH with pronounced iron clustering. In-situ spectroscopy and ab-initio calculations reveal that these structural features maximize the conversion of the NiFe-LDH to the catalytic active phase and minimize the energy barrier, improving catalytic efficiency. When used as the anode in an anion exchange membrane water electrolyzer operating at 70 °C, our material delivers 1 A cm⁻² at 1.69 V in a 5 cm2 full-cell setup, with notable durability compared to conventional NiFe-LDHs. This scalable approach could considerably lower the cost of green hydrogen production by enabling more efficient alkaline electrolyzers.

UR - https://www.scopus.com/pages/publications/105010159479

U2 - 10.1038/s41467-025-61356-2

DO - 10.1038/s41467-025-61356-2

M3 - Article

C2 - 40610453

AN - SCOPUS:105010159479

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 6138

ER -

Scalable synthesis of NiFe-layered double hydroxide for efficient anion exchange membrane electrolysis

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